Yongyi Yang
- Harris Perlstein Professor of Electrical and Computer Engineering
- Professor of Biomedical Engineering
Education
Ph.D., Illinois Institute of Technology, 1994
M.S., AM, Illinois Institute of Technology,1992
M.S.E.E., Northern Jiaotong University, Beijing, China,1988
B.S.E.E., Northern Jiaotong University, Beijing, China,1985
Research Interests
Yongyi Yang has research interests in the fields of image processing, medical imaging, machine learning, color vision, and optical information processing. He has authored or co-authored over 300 publications in these areas. His current research topics include: 1) tomographic image reconstruction methods for cardiac and pediatric kidney imaging, 2) Computer-aided diagnosis techniques for breast cancer detection in mammography, 3) Modeling of image similarity from human observers for content-based image retrieval, 4) Construction of brain atlas of adults without dementia for neuroimaging studies of age-related neurological diseases, 5) Multispectral infrared imaging of the iris for diagnostic ophthalmology, and 6) Optimization of the use of video technologies in policing.
Yang is currently a Senior Associate Editor for IEEE Transactions on Image Processing. He has also been an Associate Editor for IEEE Transactions on Image Processing, and a Guest Editor for multiple special issues of Pattern Recognition and IEEE Transactions on Selected Topics for Signal Processing. He has served on the IEEE Bio Imaging and Signal Processing (BISP) Technical Committee. Dr. Yang is also a frequent participant in NIH study sections and NSF review panels. He chaired a study section for NIH P41 Biomedical Technology Resource Centers in 2015. He is a Fellow of IEEE and AMIBE.
Awards
- Fellow, Institute of Electrical and Electronics Engineers (IEEE), "For contributions to medical image recovery and analysis," 2021.
- Fellow, American Institute for Medical and Biological Engineering (AIMBE), 鈥淔or outstanding contributions to medical image processing and analysis,鈥 2018.
- Sigma Xi Research Award, Senior Faculty Division, IIT, 2010.
- Best Student Paper Award, IEEE Inter. Symp. on Biomedical Imaging: from Nano to Macro, 2014.
- Top 10% Paper Recognition, IEEE Inter. Conf. on Image Processing, 2015.
- Paper recognition: Physics in Medicine and Biology, Highlights collection of 2011 (鈥渇or their presentation of outstanding new research, receipt of the highest praise from our international referees and the highest number of downloads last year鈥), 2011.
- Paper recognition: Physics in Medicine and Biology, two papers recognized by Institute of Physics Select (鈥渇or their novelty, significance and potential impact on future research鈥), 2006.
- Best Student Paper Award, IEEE Medical Imaging Conference, 2006.
- Honorable Mention Poster Award (one of three), SPIE International Symposium Medical Imaging, 2005.
Publications
Image and signal recovery
[1] Y. Yang, N. P. Galatsanos, and A. K. Katsaggelos, 鈥淩egularized reconstruction to reduce blocking artifacts of block discrete cosine transform compressed images,鈥 IEEE Trans. on Circuits and Systems for Video Tech., vol. 3, no. 6, pp. 421-432, 1993.
[2] Y. Yang, N. P. Galatsanos, and H. Stark, 鈥淧rojection-based blind deconvolution,鈥 J. Opt. Soc. Am. A, vol. 11, no. 9, pp. 2401-2409, 1994.
[3] Y. Yang, N. Galatsanos, and A. Katsaggelos, 鈥淧rojection-based spatially-adaptive reconstruction of block transform compressed images,鈥 IEEE Trans. on Image Processing, vol. 4, no. 7, pp. 896-908, 1995.
[4] Y. Yang and N. P. Galatsanos, 鈥淩emoval of compression artifacts using projections onto convex sets and line process modeling,鈥 IEEE Trans. on Image Processing, vol. 6, no. 10, pp. 1345-1357, 1997.
[5] Y. Yang and H. Stark, 鈥淒esign of self-healing arrays using vector space projections,鈥 IEEE Trans. on Antennas and Propagation, vol. 49, no. 4, pp. 526-534, 2001.
[6] M. Choi, Y. Yang, and N. P. Galatsanos, 鈥淢ultichannel regularized recovery of compressed video sequences,鈥 IEEE Trans. on Circuits and Systems II, vol. 48, no. 4, pp. 376-387, 2001.
[7] Y. Yang, J. Brankov, and M. Wernick, 鈥淎 computationally efficient approach for accurate content-adaptive mesh generation,鈥 IEEE Trans. on Image Processing, vol. 12, no. 8, pp. 866-881, 2003.
[8] J. Brankov, Y. Yang, M. N. Wernick, 鈥淐ontent-adaptive mesh modeling for tomographic image reconstruction,鈥 IEEE Trans. on Medical Imaging, vol. 23, pp. 202-212, 2004.
[9] P. Dong, J. Brankov, N. P. Galatsanos, Y. Yang, and F. Davoine, 鈥淒igital watermarking robust to geometric distortions,鈥 IEEE Trans. on Image Processing, vol. 14, pp. 2140-2150, 2005.
[10] M. N. Wernick, Y. Yang, I. Mondal, D. Chapman, M. Hasnah, C. Parham, E. Pisano and Z. Zhong, 鈥淐omputation of mass-density images from x-ray refraction-angle images,鈥 Phys. Med. Biol., vol. 51, pp. 1769-1778, 2006.
Spatiotemporal (4D) image reconstruction
[11] E. Gravier and Y. Yang, 鈥淢otion-compensated reconstruction of tomographic image sequences,鈥 IEEE Trans. on Nuclear Science, vol. 52, pp. 51-56, 2005.
[12] E. Gravier, Y. Yang, M. A. King, and M. Jin, 鈥淔ully 4D motion-compensated reconstruction of cardiac SPECT images,鈥 Phys. Med. Biol., vol. 51, pp. 4603-4619, 2006.
[13] M. Jin, Y. Yang, and M. A. King, 鈥淩econstruction of dynamic gated cardiac SPECT,鈥 Medical Physics, vol. 33, pp. 4384-4394, 2006.
[14] E. Gravier, Y. Yang, and M. Jin, 鈥淭omographic reconstruction of dynamic cardiac image sequences,鈥 IEEE Trans. on Image Processing, vol. 16, pp. 932-942, 2007.
[15] J. G. Brankov, Y. Yang, L. Wei, I. El-Naqa, and M. N. Wernick, 鈥淟earning a channelized observer for image quality assessment,鈥 IEEE Trans. on Medical. Imaging, vol. 28, pp. 991- 999, 2009.
[16] X. Niu, Y. Yang, M. Jin, M. N. Wernick, and M. A. King, 鈥淩egularized fully 5D reconstruction of cardiac gated dynamic SPECT images,鈥 vol. 57, pp.1085-1095, IEEE Trans. on Nuclear Science, vol. 57, no. 3, pp.1085-1095, 2010.
[17] L. Li and Y. Yang, 鈥淥ptical flow estimation for a periodic image sequence,鈥 IEEE Trans. on Image Processing, vol. 19, pp.1-10, 2010.
[18] X. Niu, Y. Yang, M. Jin, M. N. Wernick, and M. A. King, 鈥淓ffects of motion, attenuation, and scatter corrections on gated cardiac SPECT reconstruction,鈥 Medical Physics, vol. 38, no. 12, pp.6571-6584, 2011.
[19] W. Qi, Y. Yang, X. Niu, M. A. King, 鈥淎 quantitative study of motion estimation methods on 4D cardiac gated SPECT reconstruction,鈥 Medical Physics, vol. 39, no. 8, pp. 5182-5193, 2012.
[20] M. Jin, X. Niu, W. Qi, Y. Yang, J. Dey, M. A. King, S. Dahlberg, and M. N. Wernick, 鈥4D reconstruction for low-dose cardiac gated SPECT,鈥 Medical Physics, vol. 40, no. 2, 2013.
[21] W. Qi, Y. Yang, M. N. Wernick, P. H. Pretorius, and M. A. King, 鈥淟imited-angle effect compensation for respiratory binned cardiac SPECT,鈥 Medical Physics, vol. 43, pp. 443-,2015.
[22] A. J. Ramon, Y. Yang, P. H. Pretorius, P. J. Slomka, K. L. Johnson, M. A. King, M. N. Wernick, 鈥淚nvestigation of dose reduction in cardiac perfusion SPECT via optimization and choice of the image reconstruction strategy,鈥 Journal of Nuclear Cardiology, pp.1-11, 2017.
[23] W. Qi, Y. Yang, C. Song, M. N. Wernick, P. H. Pretorius, and M. A. King, 鈥4D reconstruction with respiratory correction for gated myocardial perfusion SPECT,鈥 IEEE Trans. on Medical Imaging, vol. 36, no. 8, pp. 1626-1635, 2017.
Machine learning methods for computer-aided diagnosis
[24] I. El-Naqa, Y. Yang, M. Wernick, N. P. Galatsanos, and R. Nishikawa, 鈥淎 support vector machine approach for detection of microcalcifications,鈥 IEEE Trans. on Medical Imaging, vol. 21, no. 12, pp. 1552-1563, 2002.
[25] I. El-Naqa, Y. Yang, N. P. Galatsanos, and M. Wernick, 鈥淎 similarity learning approach to content based image retrieval: application to digital mammography,鈥 IEEE Trans. on Medical Imaging, vol. 23, pp. 1233-1244, 2004.
[26] L. Wei, Y. Yang, R. M. Nishikawa, and Y. Jiang, 鈥淎 study on several machine-learning methods for classification of malignant and benign clustered microcalcifications,鈥 IEEE Trans. on Medical Imaging, vol. 24, pp. 371-380, 2005.
[27] L. Wei, Y. Yang, R. M. Nishikawa, M. N. Wernick, and Alexandra Edwards, 鈥淩elevance vector machine for automatic detection of clustered microcalcifications,鈥 IEEE Trans. on Medical Imaging, vol. 24, pp. 1278-1285, 2005.
[28] J. Tang, R. M. Rangayyan, J. Xu, I. El Naqa, and Y. Yang, 鈥淐omputer-aided detection and diagnosis of breast cancer with mammography: recent advances,鈥 IEEE Trans.Information Technology in Biomedicine, vol. 13, pp. 236-251, 2009.
[29] L. Wei, Y. Yang, M. N. Wernick, and R. M. Nishikawa, 鈥淟earning of perceptual similarity from expert readers for mammogram retrieval,鈥 IEEE Journal of Selected Topics in Signal Processing, vol. 3, pp. 53-61, 2009.
[30] L. Wei, Y. Yang, and R. M. Nishikawa, 鈥淢icrocalcification classification assisted by content-based image retrieval for breast cancer diagnosis,鈥 Pattern Recognition, vol. 42, pp. 1126-1132, 2009.
[31] X. Liu, I. S. Yetik, D. L. Langer, M. A. Haider, Y. Yang, and Miles N. Wernick, 鈥淧rostate cancer segmentation with simultaneous estimation of Markov random field parameters and classes,鈥 IEEE Trans. on Medical. Imaging, vol. 28, pp. 906-915, 2009.
[32] H. Jing, Y. Yang, and R. M. Nishikawa, 鈥淒etection of clustered microcalcifications using spatial point process modeling,鈥 Phys. Med. Biol., vol. 56, no.1, pp.1-17, 2011.
[33] H. Jing, Y. Yang, and R. M. Nishikawa, 鈥淩etrieval boosted computer-aided diagnosis of clustered microcalcifications for breast cancer,鈥 Medical Physics, vol. 39, no. 2, pp.676-85, 2012.
[34] J. Wang, H. Jing, M. N. Wernick, R. M. Nishikawa, and Y. Yang, 鈥淎nalysis of perceived similarity between pairs of microcalcification clusters in mammograms,鈥 Medical Physics, vol. 41(5):051904, 2014.
[35] J. Wang, R. M. Nishikawa, and Y. Yang, 鈥淚mproving the accuracy in detection of clustered microcalcifications with a context-sensitive classification model,鈥 Medical Physics, vol. 43, pp. 159-,2016.
[36] J. Wang, R. M. Nishikawa, Y. Yang, 鈥淕lobal detection approach for clustered microcalcifications in mammograms using a deep learning network,鈥 Journal of Medical Imaging, vol. 4, no. 2, pp. 024501-, 2017.
[37] M. V. Sainz de Cea, R. M. Nishikawa, and Y. Yang, 鈥淓stimating the accuracy level among individual detections in clustered microcalcifications,鈥 IEEE Trans. Medical Imaging, vol. 36, no. 5, pp. 1162-1171, 2017.
[38] M. V. Sainz de Cea, R. M. Nishikawa, and Y. Yang, 鈥淟ocally adaptive decision in detection of clustered microcalcifications in mammograms,鈥 Physics in Medicine and Biology, 2017. Accepted.
[39] R. M. Nishikawa1, Y. Yang, J. Wang, A. Edwards, M. N. Wernick, J. Papaioannou, 鈥淚mproving radiologists ability to discriminate mammographic calcifications using retrieved similar images,鈥 Academic Radiology, 2017. Accepted.
Books
H. Stark and Y. Yang, Vector Space Projections: A Numerical Approach to Signal and Image Processing, Neural Nets, and Optics, John Wiley & Sons, Inc., New York, 1998.
Expertise
Image and signal recovery, tomographic image reconstruction, computer-aided diagnosis, machine learning, applied mathematical and statistical methods.